Pad design and process for voiding control at QFN assembly
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Transcript of Pad design and process for voiding control at QFN assembly
![Page 1: Pad design and process for voiding control at QFN assembly](https://reader036.fdocuments.net/reader036/viewer/2022062514/558a29fed8b42a4c028b4661/html5/thumbnails/1.jpg)
Pad Design and Process for Voiding Control at QFN
AssemblyDerrick Herron, Dr. Yan Liu, and
Dr. Ning-Cheng Lee
Indium Corporation
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Background• QFN prevailing due to (1) small size & light weight; (2) easy
PCB trace routing due to the use of perimeter I/O pads; (3) reduced lead inductance; and (4) good thermal and electrical performance due to the adoption of exposed copper die-pad technology
• Voiding is issue at SMT assembly due to the large coverage area, large number of thermal via, and low standoff
• Both design and process were studied for minimizing and controlling the voiding
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Parameters Studied
Parameter Sub parameter Layers
Thermal Pad on PCB
Thermal via number 0, 16, 32, 36Peripheral venting for full thermal pad
With and without
Dividing method Solder mask, venting channel (0.22 & 0.33 mm)
Thermal sub-pad shape Square, triangleThermal sub-pad number 1, 4, 8, 9
Stencil Aperture 85%, 100%
Heat HistoryReflow profile Short, long cool, long, long
hotOther heat treatment Prebake, 1 reflow, 2 reflow
QFN with 68 pads, 10mm x 10mm, 0.5mm pitch, daisy-chained, Sn surface finish
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Design of Thermal Pads on Test Board
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Reflow Profiles Used in Voiding Study
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Voiding Examples
6 INDIUM CORPORATION CONFIDENTIAL
0.22 mm
0.33 mm
The drastic difference in voiding behavior between the two sets demonstrates the tremendous impact of design and process conditions
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Definition of 3 Voiding PropertiesProperty DefinitionDiscontinuity Percentage of area under the
QFN thermal pad where the vertical metal continuity from QFN to PCB surface is interrupted
Void Average Average of multiple QFNs for void area percentage within the metallic pad of QFN
Largest Void The largest void measured for a category of QFN joints
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Individual Voiding Data Set
8 INDIUM CORPORATION CONFIDENTIAL
Dividing the thermal pads into sub-units results in an abrupt drop in the largest void but an increase in discontinuity
Net effect: a reduction in the uncontrollable, harmful large voids, replacing it with a controlled, even distribution of discontinuity
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Dividing Desired for High Via No.When the thermal via number is high, the discontinuity of a full pad becomes comparable with that of a divided pad, and the sporadic occurrence of large voids becomes a distinct disadvantage of the full pad design
36 363636
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Thermal Via Aggravate VoidingPropensity of voids at the via locations is particularly high for full pad solder joints
Thus, voiding increase w increasing via no.
If high via no. is needed, plugging the via is the best option
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Divided Pads with Peripheral Via Not Sensitive to Via No. on Voiding
The number of thermal via bears no relation with voiding for divided pads. This is attributed to the peripheral location of thermal via for those divided pads. If plugging the thermal via is not an option, design the thermal via at peripheral locations whenever possible.
16 36
16 36
16 36
16 36
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Peripheral Venting Reduce Size of The Largest Void on Full Pads Moderately
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Increase Channel Width Has No Effect on Void Ave, but Increase Channel Area & Discontinuity
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Calculated Venting Accessibility of Thermal Pad Designs
Thermal pad design
Ventingaccessibility
Full pad 4Square 4 8Triangle 4 9.66Square 9 12Triangle 8 13.66
Venting Accessibility: Perimeter length per unit area of metal pad
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Venting Accessibility Effect on Largest Void & Void Average
With increasing venting accessibility, the void average and largest void decrease readily
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Divided Pad A Preferred Design When Voiding A Major Threat
However, the advantage of voiding reduction is offset by the increase in discontinuity, particularly for the short profile. For a long cool profile, the discontinuity increases only moderately with increasing venting accessibility. In other words, when the voiding is a major threat, such as designs with a high number of thermal vias, or when a short profile is not a viable option, then a venting channel design becomes a favorable choice.
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Divided Thermal Pads- SMD vs Channel (NSMD)
The higher voiding of channel system (NSMD) is attributed to (1) thinner solder joint, (2) FR4 outgassing
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Largest Void Bigger for SMD- Due to Blocked Venting by SM
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Smaller Paste Volume Cause Slightly More Voiding - Due to Thinner Joint
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Effect of Profile on VoidingThe short profile is preferred for a low void average, while the long hot profile is better for reducing the largest void
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Prebake Aggravate Voiding Due to More Oxidation
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Double Reflow Cause Higher Voiding Due to More Outgassing at 2nd
Reflow
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Discussion (1)
• Prospect of thermal via– When mechanical drilled thermal via (0.3mm drill
diam/1.2mm pitch) evolve to microvia, the via pitch decreases, thermal via density may becomes higher, & voiding may worsen
• How much voiding is too much?– Voiding up to 50% or even 60% OK– But, the largest void should be < pitch
• What is less evil?– High void or uneven size distribution?
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Discussion (2)
• Patterned solder paste common approach– Multiple opens– 50-80% coverage– 0.15-0.3 mm spacing– But, still has voiding issue
• Permanent venting channel desired– Higher discontinuity may be acceptable, since
50% voiding acceptable– Controlled even distribution of discontinuity better
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Discussion (3) • Venting or being vented?
– Remove metal to form channel less obstruction on vending
– But, allow FR4 to outgass moisture from channel• What is next?
– Thin solder mask for SMD thermal pad• Short vs long hot
– Long hot more consistent, due to a wider reflow process window
– Price – slightly higher void average
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Conclusion (1)• Plugging is most effective in reducing voiding • For unplugged via situations, a full thermal pad is desired for
a low no. of via• For a high no. of thermal via, a divided thermal pad is
preferred, due to better venting capability • Placement of thermal via at the perimeter lessens voiding
caused by via• A wider venting channel has a negligible effect on voiding,
but reduces joint continuity• For a divided thermal pad, a SMD system is more favorable
than a channel (NSMD) system, with the latter suffering more voiding due to a thinner solder joint and possibly board outgassing
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Conclusion (2)• Performance of a divided thermal pad is dictated by venting
accessibility, not by the shape • Voiding decreases with increasing venting accessibility,
although the introduction of a channel area compromises the continuity of the solder joint
• Reduced solder paste volume causes more voiding• A short profile and a long hot profile are most promising in
reducing the voiding• Voiding behavior of the QFN is similar to typical SMT
voiding and increases with pad oxidation and further reflow